[[dynamic-language]]
= Dynamic Language Support

Spring provides comprehensive support for using classes and objects that have been
defined by using a dynamic language (such as Groovy) with Spring. This support lets
you write any number of classes in a supported dynamic language and have the Spring
container transparently instantiate, configure, and dependency inject the resulting
objects.

Spring's scripting support primarily targets Groovy and BeanShell. Beyond those
specifically supported languages, the JSR-223 scripting mechanism is supported
for integration with any JSR-223 capable language provider (as of Spring 4.2),
e.g. JRuby.

You can find fully working examples of where this dynamic language support can be
immediately useful in xref:languages/dynamic.adoc#dynamic-language-scenarios[Scenarios].




[[dynamic-language-a-first-example]]
== A First Example

The bulk of this chapter is concerned with describing the dynamic language support in
detail. Before diving into all of the ins and outs of the dynamic language support,
we look at a quick example of a bean defined in a dynamic language. The dynamic
language for this first bean is Groovy. (The basis of this example was taken from the
Spring test suite. If you want to see equivalent examples in any of the other
supported languages, take a look at the source code).

The next example shows the `Messenger` interface, which the Groovy bean is going to
implement. Note that this interface is defined in plain Java. Dependent objects that
are injected with a reference to the `Messenger` do not know that the underlying
implementation is a Groovy script. The following listing shows the `Messenger` interface:

[source,java,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting;

	public interface Messenger {

		String getMessage();
	}
----

The following example defines a class that has a dependency on the `Messenger` interface:

[source,java,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting;

	public class DefaultBookingService implements BookingService {

		private Messenger messenger;

		public void setMessenger(Messenger messenger) {
			this.messenger = messenger;
		}

		public void processBooking() {
			// use the injected Messenger object...
		}
	}
----

The following example implements the `Messenger` interface in Groovy:

[source,groovy,indent=0,subs="verbatim,quotes",chomp="-packages",fold="none"]
----
	package org.springframework.scripting.groovy

	// Import the Messenger interface (written in Java) that is to be implemented
	import org.springframework.scripting.Messenger

	// Define the implementation in Groovy in file 'Messenger.groovy'
	class GroovyMessenger implements Messenger {

		String message
	}
----

[NOTE]
====
To use the custom dynamic language tags to define dynamic-language-backed beans, you
need to have the XML Schema preamble at the top of your Spring XML configuration file.
You also need to use a Spring `ApplicationContext` implementation as your IoC
container. Using the dynamic-language-backed beans with a plain `BeanFactory`
implementation is supported, but you have to manage the plumbing of the Spring internals
to do so.

For more information on schema-based configuration, see xref:languages/dynamic.adoc#xsd-schemas-lang[XML Schema-based Configuration]
.
====

Finally, the following example shows the bean definitions that effect the injection of the
Groovy-defined `Messenger` implementation into an instance of the
`DefaultBookingService` class:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<?xml version="1.0" encoding="UTF-8"?>
	<beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
		xmlns:lang="http://www.springframework.org/schema/lang"
		xsi:schemaLocation="
			http://www.springframework.org/schema/beans https://www.springframework.org/schema/beans/spring-beans.xsd
			http://www.springframework.org/schema/lang https://www.springframework.org/schema/lang/spring-lang.xsd">

		<!-- this is the bean definition for the Groovy-backed Messenger implementation -->
		<lang:groovy id="messenger" script-source="classpath:Messenger.groovy">
			<lang:property name="message" value="I Can Do The Frug" />
		</lang:groovy>

		<!-- an otherwise normal bean that will be injected by the Groovy-backed Messenger -->
		<bean id="bookingService" class="x.y.DefaultBookingService">
			<property name="messenger" ref="messenger" />
		</bean>

	</beans>
----

The `bookingService` bean (a `DefaultBookingService`) can now use its private `messenger`
member variable as normal, because the `Messenger` instance that was injected into it is
a `Messenger` instance. There is nothing special going on here -- just plain Java and
plain Groovy.

Hopefully, the preceding XML snippet is self-explanatory, but do not worry unduly if it is not.
Keep reading for the in-depth detail on the whys and wherefores of the preceding configuration.




[[dynamic-language-beans]]
== Defining Beans that Are Backed by Dynamic Languages

This section describes exactly how you define Spring-managed beans in any of the
supported dynamic languages.

Note that this chapter does not attempt to explain the syntax and idioms of the supported
dynamic languages. For example, if you want to use Groovy to write certain of the classes
in your application, we assume that you already know Groovy. If you need further details
about the dynamic languages themselves, see xref:languages/dynamic.adoc#dynamic-language-resources[Further Resources] at the end of
this chapter.



[[dynamic-language-beans-concepts]]
=== Common Concepts

The steps involved in using dynamic-language-backed beans are as follows:

. Write the test for the dynamic language source code (naturally).
. Then write the dynamic language source code itself.
. Define your dynamic-language-backed beans by using the appropriate `<lang:language/>`
  element in the XML configuration (you can define such beans programmatically by
  using the Spring API, although you will have to consult the source code for
  directions on how to do this, as this chapter does not cover this type of advanced configuration).
  Note that this is an iterative step. You need at least one bean definition for each dynamic
  language source file (although multiple bean definitions can reference the same source file).

The first two steps (testing and writing your dynamic language source files) are beyond
the scope of this chapter. See the language specification and reference manual
for your chosen dynamic language and crack on with developing your dynamic language
source files. You first want to read the rest of this chapter, though, as
Spring's dynamic language support does make some (small) assumptions about the contents
of your dynamic language source files.


[[dynamic-language-beans-concepts-xml-language-element]]
==== The <lang:language/> element

The final step in the list in the xref:languages/dynamic.adoc#dynamic-language-beans-concepts[preceding section]
involves defining dynamic-language-backed bean definitions, one for each bean that you
want to configure (this is no different from normal JavaBean configuration). However,
instead of specifying the fully qualified class name of the class that is to be
instantiated and configured by the container, you can use the `<lang:language/>`
element to define the dynamic language-backed bean.

Each of the supported languages has a corresponding `<lang:language/>` element:

* `<lang:groovy/>` (Groovy)
* `<lang:bsh/>` (BeanShell)
* `<lang:std/>` (JSR-223, e.g. with JRuby)

The exact attributes and child elements that are available for configuration depends on
exactly which language the bean has been defined in (the language-specific sections
later in this chapter detail this).


[[dynamic-language-refreshable-beans]]
==== Refreshable Beans

One of the (and perhaps the single) most compelling value adds of the dynamic language
support in Spring is the "`refreshable bean`" feature.

A refreshable bean is a dynamic-language-backed bean. With a small amount of
configuration, a dynamic-language-backed bean can monitor changes in its underlying
source file resource and then reload itself when the dynamic language source file is
changed (for example, when you edit and save changes to the file on the file system).

This lets you deploy any number of dynamic language source files as part of an
application, configure the Spring container to create beans backed by dynamic
language source files (using the mechanisms described in this chapter), and (later,
as requirements change or some other external factor comes into play) edit a dynamic
language source file and have any change they make be reflected in the bean that is
backed by the changed dynamic language source file. There is no need to shut down a
running application (or redeploy in the case of a web application). The
dynamic-language-backed bean so amended picks up the new state and logic from the
changed dynamic language source file.

NOTE: This feature is off by default.

Now we can take a look at an example to see how easy it is to start using refreshable
beans. To turn on the refreshable beans feature, you have to specify exactly one
additional attribute on the `<lang:language/>` element of your bean definition. So,
if we stick with xref:languages/dynamic.adoc#dynamic-language-a-first-example[the example] from earlier in
this chapter, the following example shows what we would change in the Spring XML
configuration to effect refreshable beans:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<beans>

		<!-- this bean is now 'refreshable' due to the presence of the 'refresh-check-delay' attribute -->
		<lang:groovy id="messenger"
				refresh-check-delay="5000" <!-- switches refreshing on with 5 seconds between checks -->
				script-source="classpath:Messenger.groovy">
			<lang:property name="message" value="I Can Do The Frug" />
		</lang:groovy>

		<bean id="bookingService" class="x.y.DefaultBookingService">
			<property name="messenger" ref="messenger" />
		</bean>

	</beans>
----

That really is all you have to do. The `refresh-check-delay` attribute defined on the
`messenger` bean definition is the number of milliseconds after which the bean is
refreshed with any changes made to the underlying dynamic language source file.
You can turn off the refresh behavior by assigning a negative value to the
`refresh-check-delay` attribute. Remember that, by default, the refresh behavior is
disabled. If you do not want the refresh behavior, do not define the attribute.

If we then run the following application, we can exercise the refreshable feature.
(Please excuse the "`jumping-through-hoops-to-pause-the-execution`" shenanigans
in this next slice of code.) The `System.in.read()` call is only there so that the
execution of the program pauses while you (the developer in this scenario) go off
and edit the underlying dynamic language source file so that the refresh triggers
on the dynamic-language-backed bean when the program resumes execution.

The following listing shows this sample application:

[source,java,indent=0,subs="verbatim,quotes"]
----
	import org.springframework.context.ApplicationContext;
	import org.springframework.context.support.ClassPathXmlApplicationContext;
	import org.springframework.scripting.Messenger;

	public final class Boot {

		public static void main(final String[] args) throws Exception {
			ApplicationContext ctx = new ClassPathXmlApplicationContext("beans.xml");
			Messenger messenger = (Messenger) ctx.getBean("messenger");
			System.out.println(messenger.getMessage());
			// pause execution while I go off and make changes to the source file...
			System.in.read();
			System.out.println(messenger.getMessage());
		}
	}
----

Assume then, for the purposes of this example, that all calls to the `getMessage()`
method of `Messenger` implementations have to be changed such that the message is
surrounded by quotation marks. The following listing shows the changes that you
(the developer) should make to the `Messenger.groovy` source file when the
execution of the program is paused:

[source,groovy,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting

	class GroovyMessenger implements Messenger {

		private String message = "Bingo"

		public String getMessage() {
			// change the implementation to surround the message in quotes
			return "'" + this.message + "'"
		}

		public void setMessage(String message) {
			this.message = message
		}
	}
----

When the program runs, the output before the input pause will be `I Can Do The Frug`.
After the change to the source file is made and saved and the program resumes execution,
the result of calling the `getMessage()` method on the dynamic-language-backed
`Messenger` implementation is `'I Can Do The Frug'` (notice the inclusion of the
additional quotation marks).

Changes to a script do not trigger a refresh if the changes occur within the window of
the `refresh-check-delay` value. Changes to the script are not actually picked up until
a method is called on the dynamic-language-backed bean. It is only when a method is
called on a dynamic-language-backed bean that it checks to see if its underlying script
source has changed. Any exceptions that relate to refreshing the script (such as
encountering a compilation error or finding that the script file has been deleted)
results in a fatal exception being propagated to the calling code.

The refreshable bean behavior described earlier does not apply to dynamic language
source files defined with the `<lang:inline-script/>` element notation (see
xref:languages/dynamic.adoc#dynamic-language-beans-inline[Inline Dynamic Language Source Files]). Additionally, it applies only to beans where
changes to the underlying source file can actually be detected (for example, by code
that checks the last modified date of a dynamic language source file that exists on the
file system).


[[dynamic-language-beans-inline]]
==== Inline Dynamic Language Source Files

The dynamic language support can also cater to dynamic language source files that are
embedded directly in Spring bean definitions. More specifically, the
`<lang:inline-script/>` element lets you define dynamic language source immediately
inside a Spring configuration file. An example might clarify how the inline script
feature works:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<lang:groovy id="messenger">
		<lang:inline-script>

			package org.springframework.scripting.groovy

			import org.springframework.scripting.Messenger

			class GroovyMessenger implements Messenger {
				String message
			}

		</lang:inline-script>
		<lang:property name="message" value="I Can Do The Frug" />
	</lang:groovy>
----

If we put to one side the issues surrounding whether it is good practice to define
dynamic language source inside a Spring configuration file, the `<lang:inline-script/>`
element can be useful in some scenarios. For instance, we might want to quickly add a
Spring `Validator` implementation to a Spring MVC `Controller`. This is but a moment's
work using inline source. (See xref:languages/dynamic.adoc#dynamic-language-scenarios-validators[Scripted Validators] for such an
example.)


[[dynamic-language-beans-ctor-injection]]
==== Understanding Constructor Injection in the Context of Dynamic-language-backed Beans

There is one very important thing to be aware of with regard to Spring's dynamic
language support. Namely, you can not (currently) supply constructor arguments
to dynamic-language-backed beans (and, hence, constructor-injection is not available for
dynamic-language-backed beans). In the interests of making this special handling of
constructors and properties 100% clear, the following mixture of code and configuration
does not work:

.An approach that cannot work
[source,groovy,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting.groovy

	import org.springframework.scripting.Messenger

	// from the file 'Messenger.groovy'
	class GroovyMessenger implements Messenger {

		GroovyMessenger() {}

		// this constructor is not available for Constructor Injection
		GroovyMessenger(String message) {
			this.message = message;
		}

		String message

		String anotherMessage
	}
----

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<lang:groovy id="badMessenger"
		script-source="classpath:Messenger.groovy">
		<!-- this next constructor argument will not be injected into the GroovyMessenger -->
		<!-- in fact, this isn't even allowed according to the schema -->
		<constructor-arg value="This will not work" />

		<!-- only property values are injected into the dynamic-language-backed object -->
		<lang:property name="anotherMessage" value="Passed straight through to the dynamic-language-backed object" />

	</lang>
----

In practice this limitation is not as significant as it first appears, since setter
injection is the injection style favored by the overwhelming majority of developers
(we leave the discussion as to whether that is a good thing to another day).



[[dynamic-language-beans-groovy]]
=== Groovy Beans

This section describes how to use beans defined in Groovy in Spring.

The Groovy homepage includes the following description:

"`Groovy is an agile dynamic language for the Java 2 Platform that has many of the
features that people like so much in languages like Python, Ruby and Smalltalk, making
them available to Java developers using a Java-like syntax.`"

If you have read this chapter straight from the top, you have already
xref:languages/dynamic.adoc#dynamic-language-a-first-example[seen an example] of a Groovy-dynamic-language-backed
bean. Now consider another example (again using an example from the Spring test suite):

[source,java,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting;

	public interface Calculator {

		int add(int x, int y);
	}
----

The following example implements the `Calculator` interface in Groovy:

[source,groovy,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting.groovy

	// from the file 'calculator.groovy'
	class GroovyCalculator implements Calculator {

		int add(int x, int y) {
			x + y
		}
	}
----

The following bean definition uses the calculator defined in Groovy:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<!-- from the file 'beans.xml' -->
	<beans>
		<lang:groovy id="calculator" script-source="classpath:calculator.groovy"/>
	</beans>
----

Finally, the following small application exercises the preceding configuration:

[source,java,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting;

	import org.springframework.context.ApplicationContext;
	import org.springframework.context.support.ClassPathXmlApplicationContext;

	public class Main {

		public static void main(String[] args) {
			ApplicationContext ctx = new ClassPathXmlApplicationContext("beans.xml");
			Calculator calc = ctx.getBean("calculator", Calculator.class);
			System.out.println(calc.add(2, 8));
		}
	}
----

The resulting output from running the above program is (unsurprisingly) `10`.
(For more interesting examples, see the dynamic language showcase project for a more
complex example or see the examples xref:languages/dynamic.adoc#dynamic-language-scenarios[Scenarios] later in this chapter).

You must not define more than one class per Groovy source file. While this is perfectly
legal in Groovy, it is (arguably) a bad practice. In the interests of a consistent
approach, you should (in the opinion of the Spring team) respect the standard Java
conventions of one (public) class per source file.


[[dynamic-language-beans-groovy-customizer]]
==== Customizing Groovy Objects by Using a Callback

The `GroovyObjectCustomizer` interface is a callback that lets you hook additional
creation logic into the process of creating a Groovy-backed bean. For example,
implementations of this interface could invoke any required initialization methods,
set some default property values, or specify a custom `MetaClass`. The following listing
shows the `GroovyObjectCustomizer` interface definition:

[source,java,indent=0,subs="verbatim,quotes"]
----
	public interface GroovyObjectCustomizer {

		void customize(GroovyObject goo);
	}
----

The Spring Framework instantiates an instance of your Groovy-backed bean and then
passes the created `GroovyObject` to the specified `GroovyObjectCustomizer` (if one
has been defined). You can do whatever you like with the supplied `GroovyObject`
reference. We expect that most people want to set a custom `MetaClass` with this
callback, and the following example shows how to do so:

[source,java,indent=0,subs="verbatim,quotes"]
----
	public final class SimpleMethodTracingCustomizer implements GroovyObjectCustomizer {

		public void customize(GroovyObject goo) {
			DelegatingMetaClass metaClass = new DelegatingMetaClass(goo.getMetaClass()) {

				public Object invokeMethod(Object object, String methodName, Object[] arguments) {
					System.out.println("Invoking '" + methodName + "'.");
					return super.invokeMethod(object, methodName, arguments);
				}
			};
			metaClass.initialize();
			goo.setMetaClass(metaClass);
		}

	}
----

A full discussion of meta-programming in Groovy is beyond the scope of the Spring
reference manual. See the relevant section of the Groovy reference manual or do a
search online. Plenty of articles address this topic. Actually, making use of a
`GroovyObjectCustomizer` is easy if you use the Spring namespace support, as the
following example shows:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<!-- define the GroovyObjectCustomizer just like any other bean -->
	<bean id="tracingCustomizer" class="example.SimpleMethodTracingCustomizer"/>

		<!-- ... and plug it into the desired Groovy bean via the 'customizer-ref' attribute -->
		<lang:groovy id="calculator"
			script-source="classpath:org/springframework/scripting/groovy/Calculator.groovy"
			customizer-ref="tracingCustomizer"/>
----

If you do not use the Spring namespace support, you can still use the
`GroovyObjectCustomizer` functionality, as the following example shows:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<bean id="calculator" class="org.springframework.scripting.groovy.GroovyScriptFactory">
		<constructor-arg value="classpath:org/springframework/scripting/groovy/Calculator.groovy"/>
		<!-- define the GroovyObjectCustomizer (as an inner bean) -->
		<constructor-arg>
			<bean id="tracingCustomizer" class="example.SimpleMethodTracingCustomizer"/>
		</constructor-arg>
	</bean>

	<bean class="org.springframework.scripting.support.ScriptFactoryPostProcessor"/>
----

NOTE: You may also specify a Groovy `CompilationCustomizer` (such as an `ImportCustomizer`)
or even a full Groovy `CompilerConfiguration` object in the same place as Spring's
`GroovyObjectCustomizer`. Furthermore, you may set a common `GroovyClassLoader` with custom
configuration for your beans at the `ConfigurableApplicationContext.setClassLoader` level;
this also leads to shared `GroovyClassLoader` usage and is therefore recommendable in case of
a large number of scripted beans (avoiding an isolated `GroovyClassLoader` instance per bean).



[[dynamic-language-beans-bsh]]
=== BeanShell Beans

This section describes how to use BeanShell beans in Spring.

The https://beanshell.github.io/intro.html[BeanShell homepage] includes the following
description:

----
BeanShell is a small, free, embeddable Java source interpreter with dynamic language
features, written in Java. BeanShell dynamically runs standard Java syntax and
extends it with common scripting conveniences such as loose types, commands, and method
closures like those in Perl and JavaScript.
----

In contrast to Groovy, BeanShell-backed bean definitions require some (small) additional
configuration. The implementation of the BeanShell dynamic language support in Spring is
interesting, because Spring creates a JDK dynamic proxy that implements all of the
interfaces that are specified in the `script-interfaces` attribute value of the
`<lang:bsh>` element (this is why you must supply at least one interface in the value
of the attribute, and, consequently, program to interfaces when you use BeanShell-backed
beans). This means that every method call on a BeanShell-backed object goes through the
JDK dynamic proxy invocation mechanism.

Now we can show a fully working example of using a BeanShell-based bean that implements
the `Messenger` interface that was defined earlier in this chapter. We again show the
definition of the `Messenger` interface:

[source,java,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.scripting;

	public interface Messenger {

		String getMessage();
	}
----

The following example shows the BeanShell "`implementation`" (we use the term loosely here)
of the `Messenger` interface:

[source,java,indent=0,subs="verbatim,quotes"]
----
	String message;

	String getMessage() {
		return message;
	}

	void setMessage(String aMessage) {
		message = aMessage;
	}
----

The following example shows the Spring XML that defines an "`instance`" of the above
"`class`" (again, we use these terms very loosely here):

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<lang:bsh id="messageService" script-source="classpath:BshMessenger.bsh"
		script-interfaces="org.springframework.scripting.Messenger">

		<lang:property name="message" value="Hello World!" />
	</lang:bsh>
----

See xref:languages/dynamic.adoc#dynamic-language-scenarios[Scenarios] for some scenarios where you might want to use
BeanShell-based beans.




[[dynamic-language-scenarios]]
== Scenarios

The possible scenarios where defining Spring managed beans in a scripting language would
be beneficial are many and varied. This section describes two possible use cases for the
dynamic language support in Spring.



[[dynamic-language-scenarios-controllers]]
=== Scripted Spring MVC Controllers

One group of classes that can benefit from using dynamic-language-backed beans is that
of Spring MVC controllers. In pure Spring MVC applications, the navigational flow
through a web application is, to a large extent, determined by code encapsulated within
your Spring MVC controllers. As the navigational flow and other presentation layer logic
of a web application needs to be updated to respond to support issues or changing
business requirements, it may well be easier to effect any such required changes by
editing one or more dynamic language source files and seeing those changes being
immediately reflected in the state of a running application.

Remember that, in the lightweight architectural model espoused by projects such as
Spring, you typically aim to have a really thin presentation layer, with all
the meaty business logic of an application being contained in the domain and service
layer classes. Developing Spring MVC controllers as dynamic-language-backed beans lets
you change presentation layer logic by editing and saving text files. Any
changes to such dynamic language source files is (depending on the configuration)
automatically reflected in the beans that are backed by dynamic language source files.

NOTE: To effect this automatic "`pickup`" of any changes to dynamic-language-backed
beans, you have to enable the "`refreshable beans`" functionality. See
xref:languages/dynamic.adoc#dynamic-language-refreshable-beans[Refreshable Beans] for a full treatment of this feature.

The following example shows an `org.springframework.web.servlet.mvc.Controller` implemented
by using the Groovy dynamic language:

[source,groovy,indent=0,subs="verbatim,quotes",chomp="-packages"]
----
	package org.springframework.showcase.fortune.web

	import org.springframework.showcase.fortune.service.FortuneService
	import org.springframework.showcase.fortune.domain.Fortune
	import org.springframework.web.servlet.ModelAndView
	import org.springframework.web.servlet.mvc.Controller

	import jakarta.servlet.http.HttpServletRequest
	import jakarta.servlet.http.HttpServletResponse

	// from the file '/WEB-INF/groovy/FortuneController.groovy'
	class FortuneController implements Controller {

		@Property FortuneService fortuneService

		ModelAndView handleRequest(HttpServletRequest request,
				HttpServletResponse httpServletResponse) {
			return new ModelAndView("tell", "fortune", this.fortuneService.tellFortune())
		}
	}
----

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<lang:groovy id="fortune"
			refresh-check-delay="3000"
			script-source="/WEB-INF/groovy/FortuneController.groovy">
		<lang:property name="fortuneService" ref="fortuneService"/>
	</lang:groovy>
----



[[dynamic-language-scenarios-validators]]
=== Scripted Validators

Another area of application development with Spring that may benefit from the
flexibility afforded by dynamic-language-backed beans is that of validation. It can
be easier to express complex validation logic by using a loosely typed dynamic language
(that may also have support for inline regular expressions) as opposed to regular Java.

Again, developing validators as dynamic-language-backed beans lets you change
validation logic by editing and saving a simple text file. Any such changes is
(depending on the configuration) automatically reflected in the execution of a
running application and would not require the restart of an application.

NOTE: To effect the automatic "`pickup`" of any changes to dynamic-language-backed
beans, you have to enable the 'refreshable beans' feature. See
xref:languages/dynamic.adoc#dynamic-language-refreshable-beans[Refreshable Beans] for a full and detailed treatment of this feature.

The following example shows a Spring `org.springframework.validation.Validator`
implemented by using the Groovy dynamic language (see xref:core/validation/validator.adoc[Validation using Spring’s Validator interface]
 for a discussion of the
`Validator` interface):

[source,groovy,indent=0,subs="verbatim,quotes"]
----
	import org.springframework.validation.Validator
	import org.springframework.validation.Errors
	import org.springframework.beans.TestBean

	class TestBeanValidator implements Validator {

		boolean supports(Class clazz) {
			return TestBean.class.isAssignableFrom(clazz)
		}

		void validate(Object bean, Errors errors) {
			if(bean.name?.trim()?.size() > 0) {
				return
			}
			errors.reject("whitespace", "Cannot be composed wholly of whitespace.")
		}
	}
----




[[dynamic-language-final-notes]]
== Additional Details

This last section contains some additional details related to the dynamic language support.



[[dynamic-language-final-notes-aop]]
=== AOP -- Advising Scripted Beans

You can use the Spring AOP framework to advise scripted beans. The Spring AOP
framework actually is unaware that a bean that is being advised might be a scripted
bean, so all of the AOP use cases and functionality that you use (or aim to use)
work with scripted beans. When you advise scripted beans, you cannot use class-based
proxies. You must use xref:core/aop/proxying.adoc[interface-based proxies].

You are not limited to advising scripted beans. You can also write aspects themselves
in a supported dynamic language and use such beans to advise other Spring beans.
This really would be an advanced use of the dynamic language support though.



[[dynamic-language-final-notes-scopes]]
=== Scoping

In case it is not immediately obvious, scripted beans can be scoped in the same way as
any other bean. The `scope` attribute on the various `<lang:language/>` elements lets
you control the scope of the underlying scripted bean, as it does with a regular
bean. (The default scope is xref:core/beans/factory-scopes.adoc#beans-factory-scopes-singleton[singleton],
as it is with "`regular`" beans.)

The following example uses the `scope` attribute to define a Groovy bean scoped as
a xref:core/beans/factory-scopes.adoc#beans-factory-scopes-prototype[prototype]:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<?xml version="1.0" encoding="UTF-8"?>
	<beans xmlns="http://www.springframework.org/schema/beans" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
		xmlns:lang="http://www.springframework.org/schema/lang"
		xsi:schemaLocation="
			http://www.springframework.org/schema/beans https://www.springframework.org/schema/beans/spring-beans.xsd
			http://www.springframework.org/schema/lang https://www.springframework.org/schema/lang/spring-lang.xsd">

		<lang:groovy id="messenger" script-source="classpath:Messenger.groovy" scope="prototype">
			<lang:property name="message" value="I Can Do The RoboCop" />
		</lang:groovy>

		<bean id="bookingService" class="x.y.DefaultBookingService">
			<property name="messenger" ref="messenger" />
		</bean>

	</beans>
----

See xref:core/beans/factory-scopes.adoc[Bean Scopes] in xref:web/webmvc-view/mvc-xslt.adoc#mvc-view-xslt-beandefs[The IoC Container]
for a full discussion of the scoping support in the Spring Framework.



[[xsd-schemas-lang]]
=== The `lang` XML schema

The `lang` elements in Spring XML configuration deal with exposing objects that have been
written in a dynamic language (such as Groovy or BeanShell) as beans in the Spring container.

These elements (and the dynamic language support) are comprehensively covered in
xref:languages/dynamic.adoc[Dynamic Language Support]. See that section
for full details on this support and the `lang` elements.

To use the elements in the `lang` schema, you need to have the following preamble at the
top of your Spring XML configuration file. The text in the following snippet references
the correct schema so that the tags in the `lang` namespace are available to you:

[source,xml,indent=0,subs="verbatim,quotes"]
----
	<?xml version="1.0" encoding="UTF-8"?>
	<beans xmlns="http://www.springframework.org/schema/beans"
		xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
		xmlns:lang="http://www.springframework.org/schema/lang"
		xsi:schemaLocation="
			http://www.springframework.org/schema/beans https://www.springframework.org/schema/beans/spring-beans.xsd
			http://www.springframework.org/schema/lang https://www.springframework.org/schema/lang/spring-lang.xsd">

		<!-- bean definitions here -->

	</beans>
----




[[dynamic-language-resources]]
== Further Resources

The following links go to further resources about the various dynamic languages referenced
in this chapter:

* The https://www.groovy-lang.org/[Groovy] homepage
* The https://beanshell.github.io/intro.html[BeanShell] homepage
* The https://www.jruby.org[JRuby] homepage
